U.S. patent number 4,815,137 [Application Number 06/927,503] was granted by the patent office on 1989-03-21 for voiceband signal classification.
This patent grant is currently assigned to American Telephone and Telegraph Company, AT&T Bell Laboratories. Invention is credited to Nevio Benvenuto.
United States Patent |
4,815,137 |
Benvenuto |
March 21, 1989 |
Voiceband signal classification
Abstract
A signal is classified as being one among a plurality of
classifications by employing a prescribed relationship between
absolute moments of a complex low-pass version of the signal.
Specifically, the prescribed relationship is related to the second
order moment of the magnitude of the complex low-pass version being
normalized by the first order moment squared. This results in a
so-called normalized variance which is compared to predetermined
threshold values to classify the signal as having one of a
plurality of modulation schemes, e.g., FSK, PSK or QAM. In another
embodiment, a signal is classified as being speech or voiceband
data. This is achieved by employing a phase relationship, i.e., the
sign, of the autocorrelation of a complex low-pass version of the
signal and the normalized variance. If the autocorrelation has a
prescribed phase or the normalized variance is greater than a
predetermined value the signal is speech, otherwise it is voiceband
data.
Inventors: |
Benvenuto; Nevio (Neptune,
NJ) |
Assignee: |
American Telephone and Telegraph
Company (New York, NY)
AT&T Bell Laboratories (Murray Hill, NJ)
|
Family
ID: |
25454820 |
Appl.
No.: |
06/927,503 |
Filed: |
November 6, 1986 |
Current U.S.
Class: |
704/234; 341/143;
704/211; 704/217; 379/93.28; 379/351 |
Current CPC
Class: |
H04B
14/04 (20130101); H04L 27/0012 (20130101) |
Current International
Class: |
H04B
14/04 (20060101); H04L 27/00 (20060101); G10L
005/06 () |
Field of
Search: |
;381/29-51
;364/513,513.5 ;370/81 ;379/142,164,351,416 ;341/143 |
References Cited
[Referenced By]
U.S. Patent Documents
Other References
"Visual Pattern Recognition by Moment Invariants", M. K. Hu, I.R.E.
Transactions on Information Theory, Feb. 1962, pp. 179-187. .
IEEE Transactions on Communications, vol. COM-30, No. 4, Apr.
1982--Highly Sensitive Speech Detector and High-Speed Voiceband
Data Discriminator in DSI-ADPCM Systems by Yohtaro Yatsuzuka. .
IBM Technical Disclosure Bulletin vol. 26, No. 1, Jun.
1983--Voice/Data Detector and Discriminator for Use in Transform
Speech Coders by D. R. Irvin..
|
Primary Examiner: Salce; Patrick R.
Assistant Examiner: Voeltz; Emanuel Todd
Attorney, Agent or Firm: Stafford; Thomas
Claims
What is claimed is:
1. Apparatus for classifying a signal comprising,
means for generating a complex low-pass version of an incoming
signal,
means for generating absolute moments of said complex low-pass
version, and
means for utilizing a prescribed relationship of said moments for
classifying said incoming signal as one of a plurality of
classifications.
2. The apparatus as defined in claim 1 wherein said means for
generating said absolute moments includes means for generating the
magnitude of said complex low-pass version, means for generating a
first order moment of said magnitude and means for generating a
second order moment of said magnitude.
3. The apparatus as defined in claim 2 wherein said means for
utilizing includes means for normalizing said second order moment
with a prescribed relationship of said first order moment to obtain
a normalized variance of said complex low-pass version of said
incoming signal.
4. The apparatus as defined in claim 3 wherein said means for
normalizing includes means for squaring said first order moment and
means for obtaining the ratio of said second order moment to said
square of said first order moment minus one (1), said ratio minus
one being said normalized variance of said complex low-pass version
of said incoming signal.
5. The apparatus as defined in claim 3 wherein said means for
utilizing further includes means for comparing said normalized
variance with predetermined threshold values to classify said
incoming signal as having one of a plurality of modulation
schemes.
6. The apparatus as defined in claim 3 wherein said means for
utilizing further includes means for comparing said normalized
variance with a predetermined threshold value to classify said
incoming signal as being either speech or voiceband data.
7. The apparatus as defined in claim 4 further including means for
generating an autocorrelation of said complex low-pass version of
said incoming signal and wherein said means for utilizing includes
means for employing a prescribed characteristic of said
autocorrelation and said normalized variance to classify said
incoming signal as one of a plurality of classifications.
8. The apparatus as defined in claim 7 wherein said incoming signal
is a digital signal having a predetermined sample interval and
wherein said means for generating said autocorrelation generates
said autocorrelation at a prescribed delay interval, said delay
interval being a predetermined number of said sample intervals.
9. The apparatus as defined in claim 8 wherein said means for
utilizing further includes means for generating a first
characteristic of said autocorrelation and means for comparing said
first characteristic to a first predetermined threshold value and
means for comparing said normalized variance to a second
predetermined threshold, said incoming signal being speech if
either said first or second threshold is exceeded and being
voiceband data otherwise.
10. The apparatus as defined in claim 9 wherein said first
characteristic is related to the phase of said autocorrelation.
11. Apparatus for classifying a signal comprising,
means for generating a complex low-pass version of an incoming
signal,
means for generating an autocorrelation of said complex low-pass
version of said incoming signal,
means for generating a first characteristic representative of phase
of said autocorrelation, and
means for utilizing said first characteristic to classify said
incoming signal as one of a plurality of classifications.
12. The apparatus as defined in claim 11 wherein said means for
generating said first characteristic includes means for generating
a normalized real part of said autocorrelation and wherein said
means for utilizing includes means for comparing said normalized
real part to a predetermiend threshold value to classify said
incoming signal as either speech or voiceband data.
13. The apparatus as defined in claim 12 wherein means for
generating said first characteristic generates a real component of
said autocorrelation normalized by a second characteristic of said
autocorrelation.
14. The apparatus as defined in claim 13 wherein said second
characteristic is representative of the power of said incoming
signal.
15. The apparatus as defined in claim 14 wherein said second
characteristic is representative of said autocorrelation at zero
(0) delay.
16. The apparatus as defined in claim 15 wherein said incoming
signal is a digital signal sample having a predetermined sample
interval and wherein said prescribed delay interval is a
predetermined number of said sample intervals.
17. The apparatus as defined in claim 16 wherein said predetermined
number is two (2).
18. A method for classifying a signal comprising the steps of,
generating a complex low-pass version of an incoming signal,
generating absolute moments of said complex low-pass version of
said incoming signal, and
utilizing a prescribed relationship of said absolute moments for
classifying said incoming signal as one of a plurality of
classifications.
19. The method as defined in claim 18 wherein said step of
generating said absolute moments includes steps of generating a
magnitude value of said complex low-pass version of said incoming
signal, generating a first order moment of said magnitude and
generating a second order moment of said magnitude, and wherein
said step of utilizing includes a step of normalizing said second
order moment with a prescribed relationship of said first order
moment to obtain a normalized variance of said low-pass version of
said incoming signal.
20. The method as defined in claim 19 wherein said utilizing step
includes a step of comparing said normalized variance with
predetermined threshold values to classify said incoming signal as
having one of a plurality of modulation schemes.
21. The method as defined in claim 19 wherein said utilizing step
includes a step of comparing said normalized variance with a
predetermined threshold value to classify said incoming signal as
being speech or voiceband data.
Description
TECHNICAL FIELD
This invention relates to signal classifiers and, more
particularly, to an arrangement for classifying an incoming signal
among one of a plurality of classifications.
BACKGROUND OF THE INVENTION
In recent times bit rate reduction techniques have been employed to
increase transmission capacity over digital transmission
facilities. One such technique is adaptive differential pulse code
modulation (ADPCM). ADPCM is employed to increase capacity over
voiceband digital transmission facilities. Use of 32 kilobit/sec
ADPCM is increasing and, normally, doubles the capacity of T
carrier facilities. Greater transmission capacity may be realized
by judiciously transmitting the voiceband signals at still lower
bit rates than the 32 kilobit/sec rate.
The 32 kilobit/sec rate ADPCM, however, presents a problem when
transmitting certain non-voice signals. Typically, non-voice
signals, for example, voiceband data signals, are transmitted at
the 32 kilobit/sec rate ADPCM. That is, no bits are allowed to be
dropped to lower the transmission bit rate. When transmitting
"higher" bit rate voiceband data signals, for example, those
generated by a 9600 bit/sec or higher rate modem, the use of the 32
kilobit/sec so-called fixed rate ADPCM results in unacceptable bit
error rates. Consequently, the data must be retransmitted thereby
resulting in unacceptable transmission throughput. In order to
minimize this problem it is desirable to transmit the 9600 bit/sec
and higher rate voiceband data signals at an ADPCM transmission bit
rate or other PCM transmission bit rates higher than the present
fixed ADPCM bit rate of 32 kilobit/sec. Additionally, it may be
acceptable and desirable to transmit voiceband data signals having
"lower" bit rates at a bit rate less than the 32 kilobit ADPCM. In
order to effect transmission of the voiceband data signals at bit
rates higher or lower than the 32 kilobit/sec ADPCM rate, they must
be classified as to their respective baud rates and/or modulation
scheme.
Heretofore, attempts at classifying voiceband data signals have
used a so-called ordinary autocorrelation of the signal. A problem
with the use of the ordinary autocorrelation is that the results
are modulated by the carrier frequency of the data signal.
Consequently, the results of such a classifying arrangement do not
accurately reflect the baud rates or type of modulation of the
voiceband data signals.
SUMMARY OF THE INVENTION
Classification of an incoming signal is realized, in accordance
with an aspect of the invention, by employing a classification
arrangement which is based on moments of the magnitude of a complex
low-pass version of the incoming signal. More specifically, a
prescribed relationship of at least the first and second order
absolute moments of the complex low-pass version of the incoming
signal is uniquely employed to classify the incoming signal as one
of a plurality of classifications.
In a particular implementation of the invention, the prescribed
relationship is related to the second order moment normalized by
the first order moment squared of the magnitude of the complex
low-pass version of the incoming signal. This results in a
so-called normalized variance. The normalized variance is compared
to predetermined threshold values to classify the incoming signal
as having one of a plurality of modulation schemes.
In accordance with another aspect of the invention, a so-called
phase relationship, i.e., the sign, of the autocorrelation of the
complex low-pass version of the incoming signal is uniquely used to
classify the incoming signal as being either speech or voiceband
data. More specifically, the sign of the complex autocorrelation
function determined at a predetermined delay interval, i.e., lag,
is used to determine whether the incoming signal is speech or
voiceband data. In a specific embodiment, both the phase and the
normalized variance are used to make the determination that the
incoming signal is either speech or voiceband data.
BRIEF DESCRIPTION OF THE DRAWING
The invention will be more fully appreciated from the following
detailed description when considered in conjunction with the
accompanying figures, in which:
FIG. 1 shows in simplified block diagram form a signal
classification arrangement including an embodiment of the
invention; and
FIGS. 2 and 3 when combined A--A and B--B form a flow chart
illustrating operation of a classification arrangement in
accordance with aspects of the invention.
DETAILED DESCRIPTION
FIG. 1 shows in simplified block diagram form an arrangement for
classifying voice band signals in accordance with aspects of the
invention. Accordingly, shown is incoming digital signal d(n),
being supplied to multipliers 10 and 11. In this example, signal
d(n) is in linear PCM form with a sampling rate of 8 kHz. Thus, a
sample interval is 125.mu. seconds. A signal representative of cos
(.pi.n/2) is supplied from cos (.pi.n/2) generator 12 to multiplier
10. In turn, multiplier 10 yields a(n)=d(n) cos (.pi.n/2).
Similarly, a signal representative of sin (.pi.n/2) is supplied
from sin (.pi.n/2) generator 13 to multiplier 11. In turn,
multiplier 11 yields b(n)=d(n) sin (.pi.n/2). Signal a(n) is
supplied to low pass filter 14 which yields a low pass version
thereof, namely, u(n). Similarly, signal b(n) is supplied to low
pass filter 15 which also yields a low pass version thereof,
namely, v(n). In this example, low pass filters 14 and 15 are each
a second order recursive filter with a cutoff frequency at 2 kHz.
Both u(n) and v(n) are supplied to complex signal generator 16
which yields .gamma.(n)=u(n)-jv(n). .gamma.(n) is a complex low
pass version of d(n). It is noted that the complex low-pass
version, .gamma.(n), may be generated by other arrangements; one
example being a Hilbert filter. Signal .gamma.(n) is supplied to
multiplier 17, complex conjugate generator 18 and magnitude
generator 19. The complex conjugate .gamma.* (n) of the complex low
pass version signal .gamma.(n) is supplied from complex conjugate
generator 18 to delay unit 20. In turn, delay unit 20 delays each
sample representation of .gamma.* (n) a predetermined number, k, of
sample intervals. In this example, a delay k, i.e., lag, of two (2)
sample intervals is advantageously used. The delayed complex
conjugate .gamma.* (n-k) is supplied to multiplier 17 where it is
combined via multiplication with .gamma.(n) to yield
.gamma.(n).gamma.* (n-k). In turn, the combined signal
.gamma.(n).gamma.* (n-k) is supplied to averaging filter 21 which
yields the complex autocorrelation of .gamma.(n), namely, ##EQU1##
where N is a number of samples, i.e., window size, used to generate
a so-called estimate of R(k). In one example, N=1024 for
classifying voice band data signals and N=256 for classifying
between speech and voice band data. Averaging filter 21 generates
the complex autocorrelation R(k)=R(k)+.gamma.(n).gamma.*(n-k)/N,
i.e., the present estimate, R(k) is the previous estimate of R(k)
plus an averaged update portion .gamma.(n).gamma.*(n-k)/N. It is
important to note that the magnitude of the complex autocorrelation
R(k) of digital signal .gamma.(n) is independent of the carrier
frequency of the voice band data signal d(n). Consequently, the
results of the classifying arrangement of the invention are not
modulated by the voice band data signal carrier frequency and,
accurately, reflex the baud rates of the voiceband data signals.
The complex autocorrelation R(k) is supplied to normalized
magnitude unit 22 and normalized real part unit 23.
Normalized magnitude unit 22 generates
C(k)=.vertline.R(k).vertline./R(0). .vertline.R(k).vertline. is
normalized by R(0), because the signal level of d(n) may vary. R(0)
is representative of the power of incoming signal d(n). In this
example, the value of C(k) employed is, as indicated above, at
delay k=2 and the normalization factor is R(k) at delay k=0. The
output C(k), or in this example C(2), from normalized magnitude
unit 22 is supplied to threshold detectors unit 24. Threshold
detectors unit 24 includes a plurality of threshold detectors (not
shown) which discriminate between the baud rates of the voice band
data signals. The particular threshold levels are obtained by
minimizing the probability of false detection under the assumption
that C(k), at a given delay k, i.e., lag, is Gaussian distributed
over many experimental results. The delay value k=2 was selected in
this example because it yields the best overall results. However,
for lower transmission rates, e.g., 1200 and 300 FSK, a delay of
k=3 seems to produce better results. In this example, if
0.ltoreq.C(2).ltoreq.0.646 then the voice band data signal has a
baud rate of 2400/sec which relates to a 9600 or higher bit/sec
voice band data signal; if 0.646<C(2).ltoreq.0.785, the voice
band data signal has a baud rate of 1600/sec which relates to a
4800 bit/sec voice band data signal, if 0.785<C(2).ltoreq.0.878,
then the voice band data signal has a baud rate of 1200/sec which
relates to a 2400 bit/sec voice band data signal; and if
0.878<C(2).ltoreq.1, then the voice band data signals has a baud
rate of .ltoreq.600/sec which relates to voice band data signals
having bit rates less than 1200 bit/sec. The results from threshold
detectors unit 24 are supplied to utilization means 32 for use as
desired. For example, the results are advantageously used to adjust
the number of bits used in an ADPCM coder for improving the quality
and efficiency of transmitting voice band data signals.
Normalized real part unit 23 generates R.sub.d (k)=-Real[R(k)]/R(0)
which is related to the phase of the complex autocorrelation of
.gamma.(n). The real part of the complex autocorrelation R(k) is
normalized by the autocorrelation value at k=0 to compensate for
level changes in d(n). Again, the best overall results are obtained
at a delay lag k=2. Thus, if R.sub.d (2)>0 the complex
autocorrelation has a first phase, for example, a phase in the
second and third quadrants and if R.sub.d (2).ltoreq.0 the
autocorrelation has a second phase, for example, a phase in the
first and fourth quadrants. It has been determined that if R.sub.d
(2).ltoreq.0 that d(n) is a voice band data signal and if R.sub.d
(2)>0 the signal is a speech signal. The R.sub.d (2) signal is
supplied to an input of two dimensional threshold detector 25.
Threshold detector 25 is jointly responsive to R.sub.d (k) and
signal .eta. from ratio -1 unit 29 to yield a final determination
of whether d(n) is a speech or voice band data signal. As is
explained hereinafter .eta.=(m.sub.2 /m.sub.1.sup.2)-1 where
m.sub.1 is the first order absolute moment of the low pass version
.gamma.(n) of d(n), namely, ##EQU2## and m.sub.2 is the second
order absolute moment of the low pass version .gamma.(n) of d(n),
namely, ##EQU3## In this example, N is 256 for speech detection and
1024 for voice band data detection. Threshold detector 25, in this
example, yields a signal representative that d(n) is a speech
signal when R.sub.d (2)>0 or .eta.>0.3, otherwise it yields a
signal representative that d(n) is a voice band data signal. Such a
threshold detector would include two separate detectors having
their outputs ORed. The output from threshold detector 25 is
supplied to utilization means 32 for use as desired. Although both
the so-called phase R.sub.d (2) and the normalized variance .eta.
are used to distinguish between speech and voice band data, it will
be apparent that either one may be used individually to make such a
determination.
It has also been determined that it is desirable and important to
detect the type of modulation scheme used in the voice band data
signal in order to accurately distinguish between certain of the
voice band data signals. For example, use of the complex
autocorrelation related parameter C(k) described above does not
accurately distinguish a 1200 FSK signal from a 2400 bit/sec or
4800 bit/sec signal. It has been determined that a predetermined
relationship between a first order absolute moment and a second
order absolute moment of the complex low pass version .gamma.(n) of
d(n) adequately distinguishes as to whether the modulation type is
FSK, PSK, and QAM. By definition, the moment of order P of a signal
x(n) is the average of x.sup.P (n) and the absolute moment of order
P of a signal x(n) is the average of
.vertline.x(n).vertline..sup.P.
To this end, magnitude unit 19 generates
.vertline..eta.(n).vertline.=.sqroot.u.sup.2 (n)+v.sup.2 (n). Then
the first order moment of .vertline..gamma.(n).vertline. can be
evaluated as m.sub.1 =m.sub.1 +.vertline..gamma.(n).vertline./N;
and the second order moment of .vertline..gamma.(n).vertline. can
be evaluated as m.sub.2 =m.sub.2
+.vertline..gamma.(n).vertline..sup.2 /N. Again, in this example,
for detecting speech N=256 and for detecting voice band data
N=1024. Thus, the first order moment m.sub.1 of
.vertline..gamma.(n).vertline. is generated by averaging filter 26
which yields m.sub.1 =m.sub.1 +.vertline..gamma.(n).vertline./N.
Then, squarer unit 28 yields m.sub.1.sup.2 which, in turn, is
supplied to ratio -1 unit 29. Similarly, the second order moment
m.sub.2 of .vertline..gamma.(n).vertline. is generated by supplying
.vertline..gamma.(n).vertline. to squarer unit 27 to yield
.vertline..gamma.(n).vertline..sup.2 and then averaging filter 30
yields m.sub.2 =m.sub.2 +.vertline..gamma.(n).vertline..sup.2 /N.
Then, m.sub.2 is supplied to ratio -1 unit 29 which, in turn,
yields a so-called normalized variance .eta. of
.vertline..gamma.(n).vertline., namely, .eta.=(m.sub.2
/m.sub.1.sup.2)-1.
As indicated above the normalized variance .eta. is supplied to two
dimensional threshold detector 25 for use in distinguishing between
speech and voice band data signals. The normalized variance .eta.
is also supplied to threshold detectors 31 for distinguishing
between several types of voice band data modulation. In this
example, the modulation types being distinguished are frequency
shift keying (FSK), pulse shift keying (PSK) and quadrature
amplitude modulation (QAM). In this example, it has been determined
that if o<.eta..ltoreq.0.021, then the modulation type is FSK;
if 0.021<.eta..ltoreq.0.122 then the modulation type is PSK; and
if 0.122<.eta. then the modulation type is QAM. The results from
threshold detectors 31 are supplied to utilization means 32 where
they are used for determining the particular voice band data signal
being received.
Thus, it is seen that use of .eta. allows to discriminate between
FSK, PSK and QAM voice band data signals, while C(2) can be used to
discriminate among 2400 baud/sec, 1600 baud/sec, 1200 baud/sec and
600 baud/sec or lower baud signals. These latter signals are
related to 9600 bit/sec, 4800 bit/sec, 2400 bit/sec and 1200
bit/sec or lower bit rate signals. If desired C(k) at delay k=3,
i.e., C(3), can be generated as described above for C(2) and used
to discriminate between 1200 bit/sec and 300 bit/sec voice band
data signals.
In situations where it is desired only to discriminate 9600 bit/sec
voice band data signals from all others and can tolerate assigning
to the 4800 QAM voice band data signal a higher speed
classification, then use of the normalized variance .eta. for
N.gtoreq.512 is sufficient.
Preferably, the above described classification arrangements are to
be implemented on a very large scale integrated (VLSI) circuit.
However, the classification arrangements are also readily
implemented via use of a processor, for example, an array
processor. To this end, FIGS. 2 and 2 when combined A--A and B--B
form a flow chart illustrating the steps for implementing the
classification of incoming digital signals, in accordance with
aspects of the invention. Accordingly, the program routine is
entered via initialized step 201. Conditional branch point 202
tests to determine if input energy is present. If the test result
is YES, energy is present and operational block 203 causes N to be
set to N=256. As noted above N=256 is the number of samples used to
detect whether the incoming signal d(n) is speech or voice band
data. Operational block 204 causes n, R(k), m.sub.1 and m.sub.2 to
be set to n=1, R(k)=0, m.sub.1 =0 and m.sub.2 =0. Operational block
205 causes the computation of a(n)=d(n) cos (.pi.n/2). and b(n)=
d(n) sin (.pi.n/2). Operational block 206 causes generation of the
complex low pass version .gamma.(n) of incoming signal d(n) by low
pass filtering by the filter function g(n) the results of step 205,
namely .gamma.(n)=[a(n)-jb(n)]*g(n), where * indicates the
convolution function. As indicated above, in this example, a low
pass filter function g(n) is employed that is a second order
recursive filter with a cutoff frequency at 2 kHz. Operational
block 207 causes estimates of R(k), m.sub.1 and m.sub.2 to be
updated. As indicated above, R(k) is the autocorrelation of
incoming complex digital signal .gamma.(n) and the updated value is
R(k)=R(k)+.gamma.(n).gamma.*(n-k)/N where * indicates the complex
conjugate. In this example, a delay, i.e., lag of k=2 sample
intervals is used. Again m.sub.1 is the first order moment of
.vertline..gamma.(n).vertline. and its updated value is m.sub.1
=m.sub.1 +.vertline..gamma.(n).vertline./N and m.sub.2 is the
second order moment of .vertline..gamma.(n).vertline. and its
updated value is m.sub.2 =m.sub.2
+.vertline..gamma.(n).vertline.2/N. Operational block 208 causes
the setting of n=n+1. Conditional branch point 209 tests whether
n.ltoreq.N. If the test result is YES control is returned to
operational block 205 and steps 205-209 are iterated until the test
result in step 209 is NO. This indicates that the 256 samples
window has occurred over which the values of R(k), m.sub.1 and
m.sub.2 are being estimated. Then, operational block 210 causes the
following calculations to be performed: the normalized magnitude
C(k) of the complex autocorrelation of .gamma.(n), namely
C(k)=.vertline.R(k).vertline./R(0) where R(0) is the complex
autocorrelation of .gamma.(n) at delay k=0; the normalized real
part R.sub.d (2) of the complex autocorrelation at delay k=2,
namely, R.sub.d (2)=-Real[R(2)]/R(0); and the normalized variance
.eta. of the magnitude of the complex low pass version .gamma.(n)
of incoming signal d(n), namely, .eta.=(m.sub.2 /m.sub.1.sup.2)-1,
where m.sub.1 is the first order moment of
.vertline..gamma.(n).vertline. and m.sub.2 is the second order
moment of .vertline..gamma.(n).vertline. from step 207. Conditional
branch point 211 tests to determine if the incoming signal is
speech or voice band data by determining, in this example, if
R.sub.d (2)>0 or .eta.>0.3. If the test result in step 211 is
YES, operational block 212 sets an indicator that the incoming
signal is speech. Thereafter, the process is stopped via 213. If
the test result in step 211 is NO, operational block 214 sets an
indicator that the incoming signal is voice band data. Conditional
branch point 215 tests to determine if N=256. If the test result is
YES, operational block 216 sets N=1024 and n=1, and control is
returned to operational block 204. As indicated above, in this
example a window of 1024 samples is used to generate the estimates
of R(k), m.sub.1 and m.sub.2 for voice band data signals.
Thereafter, steps 204 through 211, 214 and 215 are iterated. Since
N=1024 the test result in step 215 is NO. Thereafter, operational
block 217 determines the voice band data signal parameters in this
example, as follows: if 0.ltoreq.C(2).ltoreq.0.646 then the
incoming signal baud rate is 2400/sec; if
0.646<C(2).ltoreq.0.785 then the incoming signal baud rate is
1600/sec; if 0.785<C(2).ltoreq.0.878 then the incoming signal
baud rate is 1200/sec; if 0.878<C(2).ltoreq.1 then the incoming
signal baud rate is equal to or less than 600/sec; if
0<.eta..ltoreq.0.021 then the modulation type for the incoming
signal is FSK; if 0.021<.eta..ltoreq.0.122 then the modulation
type for the incoming signal is PSK; and if 0.122<.eta. then the
modulation type for the incoming signal is QAM. Thereafter, the
process is stopped via 218.
* * * * *